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Critique of proposed limit to space--time measurement, based on Wigner's clocks and mirrors PDF

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Critique of proposed limit to space–time measurement, based on Wigner’s clocks and mirrors 5 9 9 L. Di´osi and B. Luk´acs ∗ 1 KFKI Research Institute for Particle and Nuclear Physics n a H-1525 Budapest 114, POB 49, Hungary J 6 bulletin board ref.: quant-ph/9501001 3 v January 3, 1995 1 0 0 1 0 Abstract 5 9 Based on a relation between inertial time intervals and the Rie- / h mannian curvature, we show that space–time uncertainty derived by p Ng and van Dam implies absurd uncertainties of the Riemannian cur- - vature. t n a u q : v i X r a ∗E-mail: [email protected], [email protected] 0 Recently, Ng and van Dam [1, 2] presented a proof of the intrinsic quan- tum uncertainty δℓ of any geodetic length ℓ being proportional to the one third power of the length itself: δℓ = ℓ2/3ℓ1/3 (1) P where ℓ is the Planck lenghts. In addition, they claim that an intrinsic P uncertainty of space–time metric has been derived in Refs. [1, 2]. Now, the problem deserves a discussion since, a few years ago, the present au- thors [3] pointed out that the formula (1) would certainly overestimate the uncertainty of the space–time. This formula would be the uncertainty of a distinctedworldlinewhoselengthismeasuredatthepriceoftotalignorance about the lenghts of any other neighbouring world lines. In a sense, the un- certainties of all neighbouring world lines within about a tube of diameter ℓ will charge the uncertainty of the distincted one. Calculate, forinstance, themass moftheclock whenadjustedaccording to the Eqs. (3) and (4) of Ng and van Dam: ℓ 1/3 m = m (2) P (cid:18)ℓ (cid:19) P where m is the Planck-mass. It is at least worrying that the optimum P mesurement of a lenght ℓ ≈ 1cm requires a clock of mass m ≈ 106g and, similarily, the optimum measurement of a timelike distance t ≈ 1s needs a clock with m ≈ 1016g (i.e. 1010 metric tons!). Of course, the large mass of the clock needed to reach the limit of accuracy is not a proof against the proposed fluctuation formula. But we can show that eq. (1) leads to drastic effects in the space–time continuum, strongly affecting macroscopy. That Eq. (1) seriuosly overestimates the uncertainty of space–time can now be shown by an independent elementary proof. Let us start with the formula (6) of Ng and van Dam: δt = t2/3t1/3 (3) P whereδtistheproposeduncertainty ofthetimetalonganarbitrarilychosen time-like geodesic and t is the Planck-time. This uncertainty implies a P certain uncertainty of the physical space–time geometry. One expects that the corresponding fluctuations of the local Riemann curvature are fairly small. 1 Fortunately, there exists a simple relation between a subtle triplet of time intervals on one hand and the average Riemannian curvature on the other. We recapitulate this relation according to Wigner [4]. Assume space–time is flat on average. Take a clock and in distance ℓ/2 a mirror; for simplicity’s sake let them be at rest relative to each other. Let us emit a light signal from the clock to the mirror, and let the clock measure the total flight time t1 as the signal has got back to it. Repeat the same experiment immediately after, for the flight time t2, and similarily for a third one t3. Then, the average curvature C in the space–time region swept by the light pulses is 1 t1−2t2+t3 C = . (4) 2 11c t 2 Let us obtain the quantum uncertainty δC of the above curvature. Of course, each period t (i = 1,2,3) has the same average value ℓ/c. Their i quantum uncertainties δt are also equal. According to Ng and van Dam, i any timelike geodesic length possesses the ultimate uncertainty (3) so do ours, too: ℓ 2/3 ℓ 1/3 P δt = . (5) i (cid:18) c (cid:19) (cid:18)c(cid:19) If ℓ ≫ ℓ the periods t are much larger than their fluctuations (5) and, P i consequently, we can approximate the uncertainty of the curvature (4) by an expession linear in δt : i c δC = 11ℓ2δ(t1−2t2+t3). (6) TocalculatethesquaredaveragevalueofδC,onerewritestheaboveequation in the following equivalent form: 2 c 2 2 2 2 [δC] = (cid:18)11ℓ2(cid:19) (cid:16)3[δt1] +9[δt2] +3[δt3] −3[δ(t1 +t2)]2−3[δ(t2 +t3)]2 +[δ(t1+t2+t3)]2 . (7) (cid:17) Each term on the RHS is then evaluated by means of the Eq. (3). After extracting a root, on obtains 15−6×22/3 +32/31 ℓ 2/3 P δC = . (8) p 11 ℓ (cid:18) ℓ (cid:19) 2 The averaged Riemann-tensor components are related to the averaged cur- 2 vatures (4) as, e.g., R0101 = 2C provided both clock and mirror lay along the first coordinate axis [4]. It seems plausible to assume that δC of (8) yields the order of magnitude not only for the Riemann-tensor components but for the components of Ricci-tensor as well as for the Riemann-scalar R unlessspecialstatisticalcorrelationisshownoratleastassumedbetweenthe various components of the Riemann-tensor. So, Eq. (8) yields the following estimation for the Riemann-scalar R averaged in a 4-volume ∼ ℓ4/c: 1 ℓ 4/3 δR ∼ P . (9) ℓ2 (cid:18) ℓ (cid:19) Basically, onewouldexpectwithNgandvanDamthatthesefluctuations are small. There is at least one good criterion to test their smallness. Ac- cording to the Einstein theory of general relativity, nonzero scalar curvature R assumesnonzeroenergydensity. Ifweassumethattheenergy-momentum tensor is dominated by the energy density ρ then the fluctuation (9) of the Riemann scalar would imply δρ ∼ (c2/G)R ∼ (h¯/c)ℓ−2/3ℓ−10/3, (10) P whereδρdenotestheuniversalfluctuationoftheenergydensityρaveragedin a 4-volume ∼ ℓ4/c. This fluctuation would be extremly high at small length scales. At ℓ ∼ 10−5cm, for instance, the uncertainty δρ would be in the order of water density; that is trivially excluded by experience. According to decent cosmological estimations, e.g. from galaxy counts, the average −29 −3 mass density of our Universe should not exceed 10 gcm . Then, the Eq. (10) yields ℓ ≫ 104cm which in turn means that the proposal of Ng and Dam for the uncertainty of geodesic length may not be applied for lenghts shorter than some 100 meters otherwise one might get another Universe due to the additional cosmologic mass density generated by the short range metric fluctuations. According to all these arguments, we think that Ng and van Dam in [1, 2] have in fact derived an unconditional uncertainty for a single geodesic. However, the uncertainty of a single geodesic length should not be used to calculate the intrinsic uncertainty of the space–time metric: it would need the simultaneous uncertainties of all geodesics or at least of a subtle subset of all. We pointed out that to ignore the correlations of those uncertainties would lead too high uncertainties of the space–time curvature. Finally, it is worth to mention that a detailed account of the present authors alternative to replace Eq. (1) can be found in Ref. [3]. 3 This work was supported by the grant OTKA No. 1822/1991. References [1] Y.J. Ng and H. van Dam, Mod. Phys. Lett. A9, 35 (1994). [2] Y.J. Ng and H. van Dam, Princeton report IASSNS-HEP-94/41. [3] L. Di´osi and B. Luka´cs, Phys.Lett. 142A, 331 (1989). [4] E.P. Wigner, Rev.Mod.Phys. 29 (1957, July). 4

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